Air resistance slows down the object.
The kinetic energy accelerates the object.
Friction creates a reaction between the surface and the object.
An object which is not moving is not experiencing any acceleration, other than the acceleration due to gravity, which, along with mass gives it its weight. The upward force (normal force) acting on the object is equal to but opposite to its weight, and all of the forces acting on the objects are in equilibrium so the net force is zero Newtons.
Yes an object can be accelerate if its moving along a curve path because when the object moves along a curve path it has constant speed and there is still change in velocity and change in velocity has acceleration
Yes. The centripetal force acts on any body moving along a curved path. It acts along the radius of the path and is pointed towards the centre. If friction is in the equation there will need to be a force behind the object to counter the slowing effect as well.
The observed effect of the Coriolis force, especially the deflection of objects or substances (such as air) moving along the surface of the Earth, rightward in the Northern Hemisphere and leftward in the Southern Hemisphere. The Coriolis effect is named after the French engineer Gustave Gaspard Coriolis (1792-1843).
Nothing will happen to the object's motion, it will continue along its path.
An object which is not moving is not experiencing any acceleration, other than the acceleration due to gravity, which, along with mass gives it its weight. The upward force (normal force) acting on the object is equal to but opposite to its weight, and all of the forces acting on the objects are in equilibrium so the net force is zero Newtons.
When two objects meet in motion, there is generally more force created compared to when one object is still. This is because when both objects are in motion, they have momentum which adds to the force of the collision. When one object is still, there is only the force of the moving object acting upon the still object.
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The deflective force that effects moving objects on earth and is responsible for things such as the jet stream at the top of the troposphere is known as the Coriolis Effect..The Coriolis Effect is sometimes called a "fictitious force" because there is no actual force acting upon a body in motion that causes its deflection. In fact, in cases where the Coriolis Effect is the only factor responsible for the deflection of an object, the object actually travels in a perfectly straight line, and does not deflect at all, but from our perspective, the object appears to travel along a curved trajectory..Our perception of deflection of a an object travelling in a straight line occurs because the observers (we) exist in a rotating frame of reference. We live on the planet Earth, which rotates about its axis, and the Earth's rotation causes us to perceive that an object is deflected along a curved trajectory..Watch the video referenced in the Related Links to better understand the Coriolis Effect.
Yes an object can be accelerate if its moving along a curve path because when the object moves along a curve path it has constant speed and there is still change in velocity and change in velocity has acceleration
360 degrees
In the animation above we see an object (blue box) that is already moving along when we encounter it.
This is the Coriolis Effect. The curvature appears within the rotating reference frame, in which the motion is a straight path being viewed as a curved path. In the northern hemisphere, moving objects appear to turn to the right. In the southern hemisphere, moving objects appear to turn to the left. For a path exactly along the equator, the effect disappears.
Yes. The centripetal force acts on any body moving along a curved path. It acts along the radius of the path and is pointed towards the centre. If friction is in the equation there will need to be a force behind the object to counter the slowing effect as well.
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Procession is a group of people, vehicles, or objects moving along in an orderly, formal manner.
Friction will always act in the direction opposite of the relativistic motion of two objects. If object A is moving to the right on object B, then object A will experience the friction to the left. However, object B will be moving to the left on object A and will therefore experience the friction acting towards the right.